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by Jerzy Silberring and Rolf Ekman (Editors)
The first authoritative guide to the application of this vital analytical technique.
Mass spectrometry is a powerful analytical technique that is used to identify unknown compounds, to quantify known materials and to elucidate the structural and chemical properties of molecules. In analysing the effects of experimental drugs on the brain, it is the sole technique for identifying the presence and structure of neuropeptides—substances that indicate the effect of the drug. Mass Spectrometry and Hyphenated Techniques in Neuropeptide Research specifically explains how to apply the technology to this process.
Because the book is written by mass spectrometry users, as opposed to mass spectrometrists, the focus remains on practical applications of the technique. The authors demonstrate how mass spectrometry works, how to apply the technique to research, which types of instrumentation should be used for particular requirements and how to plan experiments. Readers will learn why mass spectrometry provides more outcome features than other techniques in neuropeptide analysis, including simultaneous detection, identification of substances present in mixtures and sequence information even when the residues are modified, blocked, or unusual. Among the chapters in this comprehensive text are:
* Sequencing of Peptides by Nanospray Mass Spectrometry
* Laser-Machined Microdevices for Mass Spectrometry
* Electron Capture Dissociation of Peptides
* Synthesis of Combinatorial Peptide Libraries
* Analysis of Tissues That Reflect Nervous System Disease
Doctoral students, researchers, and industry professionals in pharmacology, chemistry, biochemistry/biotechnology and medicine will find Mass Spectrometry and Hyphenated Techniques in Neuropeptide Research to be an indispensable starting point for understanding peptides, their function, and identification.
Hardback
Pages: 576
Published: 2002
Contents
Preface
Contributors
PART 1: INTRODUCTION AND GENERAL DESCRIPTION
Introduction: Mass Spectrometry of Peptides and Proteins: A Personal Historical View (P. Roepstorff)
Neuropeptides in CNS Tissue and Body Fluids: Functional Aspects and Strategies for Their Identification, Purification and Characterisation (F. Nyberg)
Mass Spectrometry Instrumentation (A. Brinkmalm and G. Brickmalm)
PART 2: HYPHENATED TECHNIQUES
Capillary and Nano-LC Coupled with Mass Spectrometry (M. Raida)
Capillary Electrophoresis Coupled to Mass Spectrometry for Peptide and Protein Analysis (M. Wetterhall et al.)
Sequencing of Neuroeptides by Nanoelectrospray Mass Spectrometry (J. Kast and M. Wilm)
Laser-Machined Microdevices for Mass Spectrometry (Y. Lin et al.)
Endogeneous Release and Metabolism of Neuropeptides Utilising in vivo Microdialysis Microelectrospray Mass Spectrometry (P. Andrin et al.)
Biomolecular Interaction Analysis Mass Spectrometry (BIA/MS) (D. Nedelkov and R. Nelson)
Ultrasensitive MALDI-TOF-MS with Picoliter Volume Sample Handling (D. Ericsson and J. Bergquist)
PART 3: SELECTED APPLICATIONS IN PEPTIDE RESEARCH
Peptide Mapping Using MALDI-TOF-MS (U. Hellman)
Electron-Capture Dissociation of Peptides (R. Zubarev)
Synthesis of Combinatorial Peptide Libraries (K. Rolka)
Fourier Transform Ion Cyclotron Resonance Mass Spectrometry for Peptide Analysis (K. Hekansson et al.)
Peptide Sequencing Promoted by N-Terminal Derivatisation (D. Barofsky and T. Chen)
MALDI-TOF/TOF Technology for Peptide Sequencing and Protein Identification (P. Juhasz et al.)
Quantitative Analysis of Neuropeptides by MALDI-TOF-MS (J. Gobom and E. Nordhoff)
PART 4: SELECTED APPLICATIONS IN BIOSCIENCES
Characterisation of Peptides Bound to the Rat Class I MHC Molecule RTI-AIc1 (R. Jones et al.)
Analysis of Neuropeptides in Cerebrospinal Fluid and Neural and Neuroendocrine Tissues by MALDI-TOFMS (C. Nilsson)
Neuropeptides Processing (P. Suder et al.)
Measuring Neuropeptides with Single-Cell MALDI-MS (L. Li and J. Sweedler)
Dynamics of Cell Nucleus/Lymphocyte Nuclei-Associated Peptides Studied by Mass Spectrometry and Future Peptidomic Aspects (J. Berquist and R. Ekman)
Appendix (A. Sciubisz)
Index
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